The invention relates generally to a throttle plate which is part of a throttle assembly, where the throttle plate includes at least one feature, or deformation area, such as a rib or a plurality of ribs, and the throttle plate is made with reduced cost and weight, and is still able to be used with existing manufacturing and assembly processes.
Throttle assemblies are generally known and are typically used to control the flow of air into an engine. Most throttle assemblies typically have a valve which is mounted to a shaft, where the shaft is rotated (by an actuator) to change the position of the valve and therefore control the flow of air into the engine. These types of valves must withstand exposure to certain pressures and temperatures. These valves also must pass a “backfire” test, where the valve is exposed to a sudden burst of pressure from the engine. In order to pass this test, the valve must have a minimum structural robustness and rigidity. The required flat plate thickness also adds inertia loading to the actuator componentry, impacting performance and durability of the throttle assembly.
Accordingly, there exists a need for a valve for a throttle assembly, that is able to withstand a backfire test, is also lightweight, and may be manufactured with minimal or no increased cost.
In one embodiment, the present invention is a valve, such as a valve plate, which is suitable for use with a throttle assembly, and is able to withstand a backfire or backpressure test. The valve plate of the present invention is also able to be used as a replacement for existing valve plates, with minimal changes to the other components of the throttle assembly, or the manufacturing processes of the throttle assembly. In an embodiment, the valve is a valve plate which includes a flat plate, and a plastic material overmolded onto the valve plate. The valve plate includes at least one rib, and in one embodiment includes a plurality of ribs, allowing for a thinner and lighter weight plate which is manufactured at a lower cost.
In an embodiment, the valve of the present invention is a two-piece valve plate having an overlap portion. In this embodiment, the two pieces of the throttle valve overlap at the portion of the valve plate which interfaces with the shaft of the throttle assembly. The remaining portion of the plate surface includes at least one ribbed feature, and in one embodiment includes a plurality of ribbed features which reduce material usage and therefore reduce weight and cost, but also provide the required strength and rigidity.
In an embodiment, the present invention is a valve plate, including a first half having at least one deformation area, a second half having at least one deformation area, a first assembly flange integrally formed as part of the first half, and a second assembly flange integrally formed as a part of the second half. The first assembly flange and the second assembly flange are in contact with one another when the first half is assembled to the second half.
In an embodiment, the deformation area of the first half is a rib. In an embodiment, the deformation area of the second half is a rib. In an embodiment, the deformation area of the first half is a plurality of ribs. In an embodiment, the deformation area of the second half is a plurality of ribs.
In an embodiment, the valve plate includes a first flange portion integrally formed as part of the first half, and the first assembly flange is integrally formed with and offset form the first flange portion. The valve plate also includes a second flange portion integrally formed as part of the second half, where the second assembly flange is integrally formed with and offset from the second flange portion.
In an embodiment, the valve plate includes a first rib integrally formed as part of the first flange portion, and a second rib integrally formed as part of the second flange portion. The combined thickness of the first flange portion and the first rib is less than the combined thickness of the first assembly flange and the second assembly flange, and the combined thickness of the second flange portion and the second rib is less than the combined thickness of the first assembly flange and the second assembly flange.
In an embodiment, at least one assembly aperture is integrally formed as part of the first assembly flange, and at least one assembly aperture is integrally formed as part of the second assembly flange. The assembly aperture integrally formed as part of the first assembly flange and the assembly aperture integrally formed as part of the second assembly flange are aligned with one another when the first half is assembled to the second half, and the first assembly flange and the second assembly flange overlap.
In an embodiment, a shaft having a slot is integrally formed as part of the shaft. The combined thickness of the first assembly flange and the second assembly flange is such that there is a sliding fit between the first assembly flange, the second assembly flange and the slot when the valve plate is assembled with the shaft.
Further areas of applicability of the present invention will become apparent from the detailed description provided hereinafter. It should be understood that the detailed description and specific examples, while indicating the preferred embodiment of the invention, are intended for purposes of illustration only and are not intended to limit the scope of the invention.
The present invention will become more fully understood from the detailed description and the accompanying drawings, wherein:
The following description of the preferred embodiment(s) is merely exemplary in nature and is in no way intended to limit the invention, its application, or uses.
A first embodiment of a throttle plate or valve plate according to the present invention is shown in
The assembly flanges 16a,16b are each integrally formed with a flange portion 22a,22b, respectively, and each flange portion 22a,22b includes at least one deformation area. In this embodiment, the deformation areas are a singular rib 24a integrally formed as part of the flange portion 22a of the first half 12, and a singular rib 24b integrally formed as part of the flange portion 22b of the second half 14. Each rib 24a,24b is semi-circular in shape, but it is within the scope of the invention that other shapes may be used. The deformation areas may have shapes which are different than that of the ribs 24a,24b, any other shape may be used which has geometry which increases structural integrity compared to a flat surface.
In this embodiment, the thickness 26a,26b of the assembly flanges 16a,16b is substantially the same the thickness 28a,28b of the flange portions 22a,22b in the areas of the flange portions 22a,22b which are unoccupied by the ribs 24a,24b. It may be seen in
During assembly, the halves 12,14 are assembled such that the assembly flanges 16a,16b are in contact with one another, and the assembly apertures 18a,18b of the assembly flange 16a are in alignment with the assembly apertures 20a,20b of the assembly flange 16b, as shown in
Referring now to
Also, the combined thickness 36 of the assembly flanges 16a,16b results in the throttle plate 10 fitting into a slot 60 of the shaft 42 such that air leaking through the slot 60 is prevented or at least minimized. Furthermore, the width of the slot 60 and the thickness 36 of the assembly flanges 16a,16b correspond to a width and thickness that provides a sliding fit between the throttle plate 10 and the slot 60, such that during assembly the throttle plate 10 may be assembled to the shaft 42 by sliding the throttle plate 10 into the slot 60. Once the throttle plate 10 is assembled to the shaft 42, there is minimal clearance between the throttle plate 10 and the slot 60 to minimize air flow leakage through the slot 60. In an embodiment, the sliding fit is such that the throttle plate 10 is able to slide into the slot 60 using a gravity feed. The combined thickness 36 of the assembly flanges 16a,16b also allows for the throttle plate 10 to be used with the shaft 42 and slot 60 without having to change the dimensions of the slot 60, where the shaft 42 is used with existing throttle plate designs. In alternate embodiments, the dimensions of the slot 60 may be altered (within the design limits of the shaft 42) as well as the dimensions of the assembly flanges 16a,16b, which changes the corresponding thickness 36, to achieve the desired sliding fit.
An alternate embodiment of the throttle plate is shown in
Another embodiment of the invention is shown in
Also formed as part of the plate 10 is a central flange portion 62, which is located between and integrally formed with the rib portion 46c and the rib portion 46d, where the central flange portion 62 is in contact with the inner wall 48b when the throttle plate 10 is connected to the shaft 42. The assembly apertures 40a,40b are integrally formed as part of the central flange portion 62. In one embodiment, a support structure (not shown) made of plastic overmold material and located on the central flange portion 62, may also be used as well to provide the sliding fit between the plate 10 and the slot 60. In one embodiment, support rings, or stand offs 52, only one of which is shown in
Next, the throttle plate 10 is inserted into the slot 60 during assembly, such that the assembly apertures 40a,40b of the central flange portion 62 are aligned with assembly apertures 44a,44b formed as part of the shaft 42. Apertures 52a formed as part of the stand offs 52 are also aligned with the assembly apertures 44a,44b formed as part of the shaft 42. Two fasteners extend through apertures 52a formed as part of the stand offs 52 and the assembly apertures 44a,44b formed as part of the shaft 42 to secure the throttle plate 10 to the shaft 42. This results in a clamping force applied to the stand offs 52.
Again, the width 54 of the slot 60 in this embodiment is approximately 2 mm. However, the thickness 56 of the throttle plate 10 may be less than 2 mm, and the rib portions 46a,46b,46c,46d,46e,46f may be configured such that the overall width 58 of the rib portions 46a,46b,46c,46d,46e,46f corresponds to a width that provides the sliding fit between the throttle plate 10 and the slot 60.
Another embodiment of the throttle plate 10 is shown in
Integrally formed as part of the first outer flange portion 66a is a first plurality of ribs 72a, and integrally formed as part of the second outer flange portion 66b is a second plurality of ribs 72b. Each of the pluralities of ribs 72a,72b protrude away from a central axis 74 in alternating fashion, as shown in
Referring again to
The combined thickness 82 of the support structures 78a,78b and the central flange portion 68 results in the throttle plate 10 fitting into a slot 84 of a shaft 86 such that air leaking through the slot 84 is prevented or at least minimized. Furthermore, the width of the slot 84 and the combined thickness 82 of the support structures 78a,78b and the central flange portion 68 corresponds to dimensions that provide a sliding fit between the throttle plate 10 and the slot 84. Once the throttle plate 10 is assembled to the shaft 86, there is minimal clearance between the throttle plate 10 and the slot 84 to minimize air flow leakage through the slot 84. More specifically, the sliding fit between the support structures 78a,78b and slot 84 is such that air flow leakage through the slot is minimized. In an embodiment, the throttle plate 10 is able to slide into the slot 84 using a gravity feed. This minimizes air flow through the slot 84. The combined thickness 82 of the support structures 78a,78b and the central flange portion 68 also allows for the throttle plate 10 to be used with the shaft 86 and slot 84 without having to change the dimensions of the slot 84 where the shaft 86 is used with existing throttle plate designs.
The combined overall thickness 88 of the ribs 72a formed as part of the first outer flange portion 66a is less than the combined thickness 82 of the support structures 78a,78b and the central flange portion 68. Additionally, the combined overall thickness 90 of the ribs 72b formed as part of the second outer flange portion 66b is also less than the combined thickness 82 of the support structures 78a,78b and the central flange portion 68.
There are assembly apertures 92a,92b integrally formed as part of the first support structure 78a, which are respectively aligned with the assembly apertures 70a,70b formed as part of the central flange portion 68. There are also two assembly apertures (one assembly aperture 92c is shown in
Next, the throttle plate 10 is inserted into the slot 84 during assembly, such that the assembly apertures 70a,70b of the central flange portion 68 and the and the assembly apertures 92a,92b,92c integrally formed as part of the support structures 78a,78b are aligned with assembly apertures 94a,94b formed as part of the shaft 86. Apertures 98 formed as part of the stand offs 80 are also aligned with the assembly apertures 94a,94b formed as part of the shaft 86. Two fasteners extend through apertures 98 formed as part of the stand offs 80 and the assembly apertures 94a,94b formed as part of the shaft 86 to secure the throttle plate 10 to the shaft 86.
Another embodiment of the present invention is shown in
In this embodiment, as shown in
In yet another embodiment, shown in
In all embodiments, the shape of the throttle plate 10 allows for less material to be used when manufacturing the throttle plate 10, and the throttle plate 10 may be used with various existing shafts having existing slot dimensions, such that no modifications, or low cost modifications, to the existing shaft, or manufacturing processes of the throttle assembly are necessary. The throttle plate 10 may also be used with existing fixtures and grippers with only minor modifications as part of an existing manufacturing process, such as a high-volume automation assembly line, without making any significant changes to the existing manufacturing process.
The throttle plate 10 is also able to withstand exposure to various pressures and temperatures, and has the structural rigidity to pass a backfire test. Because minimal additional material is added to the throttle plate 10, there is reduced inertia loading to the actuator componentry, improving durability of actuator componentry due to lower inertia loading.
The description of the invention is merely exemplary in nature and, thus, variations that do not depart from the gist of the invention are intended to be within the scope of the invention. Such variations are not to be regarded as a departure from the spirit and scope of the invention.
This application claims the benefit of provisional application 62/988,672 filed Mar. 12, 2020. The disclosure of the above application is incorporated herein by reference.
Number | Name | Date | Kind |
---|---|---|---|
5992378 | Parkinson | Nov 1999 | A |
6354567 | Vanderveen | Mar 2002 | B1 |
20020088422 | Lozen | Jul 2002 | A1 |
20020104510 | Kotchi | Aug 2002 | A1 |
20090050106 | Bessho | Feb 2009 | A1 |
Number | Date | Country | |
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20210285405 A1 | Sep 2021 | US |
Number | Date | Country | |
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62988672 | Mar 2020 | US |